BLUE OMPHACITE IN JADEITITES FROM GUATEMALA AND JAPAN: CRYSTAL CHEMISTRY AND COLOR ORIGIN

Blue titanian omphacite has been reported previously in jadeitite from Japan by Miyajima et al. (1997) and in an enclave from the Red Wine complex in Canada by Curtis and Gittins (1978). It is now found in jadeitite from Guatemala. Optical spectroscopy, imaging, and microprobe analyses have been carried out on samples from Quebrada Seca, near Carrizal Grande, Jalapa Dept., Guatemala, and Himekawa and Noguchi, near Itoigawa, Niigata Pref., Japan. In Quebrada Seca jadeitites, omphacite occurs as clots and veins with minor phengite and titanite, trace zircon, monazite, allanite and rutile. Itoigawa jadeitites contain omphacite clots, minor titanite, and intergranular albite and analcime. Although blue color may appear pervasive in these samples, it is always restricted to omphacite in clots and veins.

Blue omphacites have relatively high TiO₂ content, but <1 wt% is sufficient to produce blue color; otherwise low-to-no-Ti omphacites are green. In a Himekawa sample TiO₂ reaches ≥ 7.5 wt% (0.2 atoms per 6 O) with FeO_T ≈ 4 wt% in 70% Na-cpx. For intense blue omphacite in a Quebrada Seca sample, TiO₂ is 1.0 – 1.8 wt% (0.02-0.05 apfu), FeO_T ≈ 3.5 wt% in 55-65% Na-cpx.

Optical absorption spectra show a dominant broad absorption band at ~720 nm overlapping a less intense one at ~600 nm, and a weak, sharp peak at ~435 nm on a sloping absorption edge. The first two absorptions are in the region where Fe²⁺ - Fe³⁺ intervalence charge transfer occurs in chain silicates, a well-known source of blue coloring. The association of blue color with elevated Ti content suggests it also plays a role in the coloring. In one sample, omphacite crystals were large enough to manifest pleochroism with blue intensity enhanced when the polarization vector is subparallel to the c axis, consistent with intervalence charge transfer between adjacent M1 sites, appropriate for Fe²⁺,Fe³⁺,and Ti⁴⁺.

In these jadeitites of HP/LT metasomatic origin, there is no tetrahedral Al in the pyroxene, and Ti content generally varies positively with Mg and negatively with Al, but Fe_T is uncorrelated. So, the exchange enhancing titanium is probably Ti+(Mg,Fe²⁺)=2(Al,Fe³⁺) in the M1 site, and Ti is entering as a sodic pyroxene component, e.g., NaTi_0.5Mg_0.5Si₂O₆. It appears Ti was carried into these rocks by an omphacite-forming fluid and precipitated as both titanite and omphacite.

Presentation Time: 1:30 PM-5:30 PM
BLUE OMPHACITE IN JADEITITES FROM GUATEMALA AND JAPAN: CRYSTAL CHEMISTRY AND COLOR ORIGIN
HARLOW, George E., Earth and Planetary Sciences, American Museum of Nat History, Central Park West at 79th Street, New York, NY 10024-5192, gharlow@amnh.org, ROSSMAN, George R., Division of Geological and Planetary Sciences MC 170-25, California Institute of Technology, 1200 E. California Blvd, Pasadena, CA 91125-2500, MATSUBARA, Satoshi, Department of Geology, National Sci Museum, 3-23-1 Hyakunincho, Shinjuku, Tokyo, 169-0073, Japan, and MIYAJIMA, Hiroshi, Fossa Magna Museum, Miyama Park, Itoigawa, 941-0056, Japan Blue titanian omphacite has been reported previously in jadeitite from Japan by Miyajima et al. (1997) and in an enclave from the Red Wine complex in Canada by Curtis and Gittins (1978). It is now found in jadeitite from Guatemala. Optical spectroscopy, imaging, and microprobe analyses have been carried out on samples from Quebrada Seca, near Carrizal Grande, Jalapa Dept., Guatemala, and Himekawa and Noguchi, near Itoigawa, Niigata Pref., Japan. In Quebrada Seca jadeitites, omphacite occurs as clots and veins with minor phengite and titanite, trace zircon, monazite, allanite and rutile. Itoigawa jadeitites contain omphacite clots, minor titanite, and intergranular albite and analcime. Although blue color may appear pervasive in these samples, it is always restricted to omphacite in clots and veins. Blue omphacites have relatively high TiO₂ content, but <1 wt% is sufficient to produce blue color; otherwise low-to-no-Ti omphacites are green. In a Himekawa sample TiO₂ reaches ≥ 7.5 wt% (0.2 atoms per 6 O) with FeO_T ≈ 4 wt% in 70% Na-cpx. For intense blue omphacite in a Quebrada Seca sample, TiO₂ is 1.0 – 1.8 wt% (0.02-0.05 apfu), FeO_T ≈ 3.5 wt% in 55-65% Na-cpx. Optical absorption spectra show a dominant broad absorption band at ~720 nm overlapping a less intense one at ~600 nm, and a weak, sharp peak at ~435 nm on a sloping absorption edge. The first two absorptions are in the region where Fe²⁺ - Fe³⁺ intervalence charge transfer occurs in chain silicates, a well-known source of blue coloring. The association of blue color with elevated Ti content suggests it also plays a role in the coloring. In one sample, omphacite crystals were large enough to manifest pleochroism with blue intensity enhanced when the polarization vector is subparallel to the c axis, consistent with intervalence charge transfer between adjacent M1 sites, appropriate for Fe²⁺,Fe³⁺,and Ti⁴⁺. In these jadeitites of HP/LT metasomatic origin, there is no tetrahedral Al in the pyroxene, and Ti content generally varies positively with Mg and negatively with Al, but Fe_T is uncorrelated. So, the exchange enhancing titanium is probably Ti+(Mg,Fe²⁺)=2(Al,Fe³⁺) in the M1 site, and Ti is entering as a sodic pyroxene component, e.g., NaTi_0.5Mg_0.5Si₂O₆. It appears Ti was carried into these rocks by an omphacite-forming fluid and precipitated as both titanite and omphacite.
2003 Seattle Annual Meeting (November 2–5, 2003)

Session No. 259 The Impact of Crystal Chemistry in the Earth Sciences (Posters): A Tribute to Charles T. Prewitt, Recipient of the 2003 Roebling Medal of the Mineralogical Society of America Washington State Convention and Trade Center: Hall 4-F 1:30 PM-5:30 PM, Wednesday, November 5, 2003 Geological Society of America Abstracts with Programs, Vol. 35, No. 6, September 2003, p. 620
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2003 Seattle Annual Meeting (November 2–5, 2003)
Paper No. 259-1